Validation methodology for PEM fuel cell three-dimensional simulation

•A comprehensive validation for three-dimensional simulation is implemented.•The combined influence of ohmic and concentration voltage losses is analyzed.•The validation methodology is clarified with details.•The liquid water in gas channel has a double effect on cell performance. For modeling and s...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2022-06, Vol.189, p.122705, Article 122705
Main Authors: Xie, Biao, Ni, Meng, Zhang, Guobin, Sheng, Xia, Tang, Houwen, Xu, Yifan, Zhai, Guizhen, Jiao, Kui
Format: Article
Language:English
Subjects:
Channel liquid water
Current density
Current density distribution
Density distribution
Electric potential
Fuel cells
Humidification
Mass transfer
Mathematical models
PEM fuel cell
Process parameters
Proton exchange membrane fuel cells
Simulation
Temperature distribution
Three dimensional models
Three-dimensional simulation
Validation
Voltage
Water
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Summary:•A comprehensive validation for three-dimensional simulation is implemented.•The combined influence of ohmic and concentration voltage losses is analyzed.•The validation methodology is clarified with details.•The liquid water in gas channel has a double effect on cell performance. For modeling and simulation of proton exchange membrane (PEM) fuel cell, validation has been an essential and challenging task. This study implements a comprehensive validation including both overall cell performance and local distribution characteristics under different operating conditions with experimental data from two public sources. Polarization curve, cell ohmic resistance, current density distribution and temperature distribution are all involved. A “three dimensional + one dimensional” (“3D+1D”) model is adopted which simplifies part of cell components in order to boost the calculation efficiency. The validation methodology is clarified by listing those undetermined model parameters and analyzing their “accessibility” as well as correlations with the three kinds of voltage losses (activation, ohmic and mass transfer). It is found that the control regions of ohmic voltage loss and concentration voltage loss overlap among a wide current density range, which may lead to misjudgment in the validation process. The details of parameter adjustment are also shared. Simulation results of the two validation tests both obtain decent agreement with the experiments and reflect consistent variation trends as the condition changes. The liquid water in gas channel is proved to have a double effect on cell performance and should be taken into careful consideration especially under low humidification and high current density working conditions.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2022.122705